#ifndef OPENMM_CUDAKERNELS_H_
#define OPENMM_CUDAKERNELS_H_
/* -------------------------------------------------------------------------- *
* OpenMM *
* -------------------------------------------------------------------------- *
* This is part of the OpenMM molecular simulation toolkit originating from *
* Simbios, the NIH National Center for Physics-Based Simulation of *
* Biological Structures at Stanford, funded under the NIH Roadmap for *
* Medical Research, grant U54 GM072970. See https://simtk.org. *
* *
* Portions copyright (c) 2008-2012 Stanford University and the Authors. *
* Authors: Peter Eastman *
* Contributors: *
* *
* This program is free software: you can redistribute it and/or modify *
* it under the terms of the GNU Lesser General Public License as published *
* by the Free Software Foundation, either version 3 of the License, or *
* (at your option) any later version. *
* *
* This program is distributed in the hope that it will be useful, *
* but WITHOUT ANY WARRANTY; without even the implied warranty of *
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the *
* GNU Lesser General Public License for more details. *
* *
* You should have received a copy of the GNU Lesser General Public License *
* along with this program. If not, see . *
* -------------------------------------------------------------------------- */
#include "CudaPlatform.h"
#include "CudaArray.h"
#include "CudaContext.h"
#include "CudaParameterSet.h"
#include "CudaSort.h"
#include "openmm/kernels.h"
#include "openmm/System.h"
#include
namespace OpenMM {
/**
* This kernel is invoked at the beginning and end of force and energy computations. It gives the
* Platform a chance to clear buffers and do other initialization at the beginning, and to do any
* necessary work at the end to determine the final results.
*/
class CudaCalcForcesAndEnergyKernel : public CalcForcesAndEnergyKernel {
public:
CudaCalcForcesAndEnergyKernel(std::string name, const Platform& platform, CudaContext& cu) : CalcForcesAndEnergyKernel(name, platform), cu(cu) {
}
/**
* Initialize the kernel.
*
* @param system the System this kernel will be applied to
*/
void initialize(const System& system);
/**
* This is called at the beginning of each force/energy computation, before calcForcesAndEnergy() has been called on
* any ForceImpl.
*
* @param context the context in which to execute this kernel
* @param includeForce true if forces should be computed
* @param includeEnergy true if potential energy should be computed
* @param groups a set of bit flags for which force groups to include
*/
void beginComputation(ContextImpl& context, bool includeForce, bool includeEnergy, int groups);
/**
* This is called at the end of each force/energy computation, after calcForcesAndEnergy() has been called on
* every ForceImpl.
*
* @param context the context in which to execute this kernel
* @param includeForce true if forces should be computed
* @param includeEnergy true if potential energy should be computed
* @param groups a set of bit flags for which force groups to include
* @return the potential energy of the system. This value is added to all values returned by ForceImpls'
* calcForcesAndEnergy() methods. That is, each force kernel may either return its contribution to the
* energy directly, or add it to an internal buffer so that it will be included here.
*/
double finishComputation(ContextImpl& context, bool includeForce, bool includeEnergy, int groups);
private:
CudaContext& cu;
};
/**
* This kernel provides methods for setting and retrieving various state data: time, positions,
* velocities, and forces.
*/
class CudaUpdateStateDataKernel : public UpdateStateDataKernel {
public:
CudaUpdateStateDataKernel(std::string name, const Platform& platform, CudaContext& cu) : UpdateStateDataKernel(name, platform), cu(cu) {
}
/**
* Initialize the kernel.
*
* @param system the System this kernel will be applied to
*/
void initialize(const System& system);
/**
* Get the current time (in picoseconds).
*
* @param context the context in which to execute this kernel
*/
double getTime(const ContextImpl& context) const;
/**
* Set the current time (in picoseconds).
*
* @param context the context in which to execute this kernel
*/
void setTime(ContextImpl& context, double time);
/**
* Get the positions of all particles.
*
* @param positions on exit, this contains the particle positions
*/
void getPositions(ContextImpl& context, std::vector& positions);
/**
* Set the positions of all particles.
*
* @param positions a vector containg the particle positions
*/
void setPositions(ContextImpl& context, const std::vector& positions);
/**
* Get the velocities of all particles.
*
* @param velocities on exit, this contains the particle velocities
*/
void getVelocities(ContextImpl& context, std::vector& velocities);
/**
* Set the velocities of all particles.
*
* @param velocities a vector containg the particle velocities
*/
void setVelocities(ContextImpl& context, const std::vector& velocities);
/**
* Get the current forces on all particles.
*
* @param forces on exit, this contains the forces
*/
void getForces(ContextImpl& context, std::vector& forces);
/**
* Get the current periodic box vectors.
*
* @param a on exit, this contains the vector defining the first edge of the periodic box
* @param b on exit, this contains the vector defining the second edge of the periodic box
* @param c on exit, this contains the vector defining the third edge of the periodic box
*/
void getPeriodicBoxVectors(ContextImpl& context, Vec3& a, Vec3& b, Vec3& c) const;
/**
* Set the current periodic box vectors.
*
* @param a the vector defining the first edge of the periodic box
* @param b the vector defining the second edge of the periodic box
* @param c the vector defining the third edge of the periodic box
*/
void setPeriodicBoxVectors(ContextImpl& context, const Vec3& a, const Vec3& b, const Vec3& c) const;
/**
* Create a checkpoint recording the current state of the Context.
*
* @param stream an output stream the checkpoint data should be written to
*/
void createCheckpoint(ContextImpl& context, std::ostream& stream);
/**
* Load a checkpoint that was written by createCheckpoint().
*
* @param stream an input stream the checkpoint data should be read from
*/
void loadCheckpoint(ContextImpl& context, std::istream& stream);
private:
CudaContext& cu;
};
/**
* This kernel modifies the positions of particles to enforce distance constraints.
*/
class CudaApplyConstraintsKernel : public ApplyConstraintsKernel {
public:
CudaApplyConstraintsKernel(std::string name, const Platform& platform, CudaContext& cu) : ApplyConstraintsKernel(name, platform),
cu(cu), hasInitializedKernel(false) {
}
/**
* Initialize the kernel.
*
* @param system the System this kernel will be applied to
*/
void initialize(const System& system);
/**
* Update particle positions to enforce constraints.
*
* @param context the context in which to execute this kernel
* @param tol the distance tolerance within which constraints must be satisfied.
*/
void apply(ContextImpl& context, double tol);
private:
CudaContext& cu;
bool hasInitializedKernel;
CUfunction applyDeltasKernel;
};
/**
* This kernel recomputes the positions of virtual sites.
*/
class CudaVirtualSitesKernel : public VirtualSitesKernel {
public:
CudaVirtualSitesKernel(std::string name, const Platform& platform, CudaContext& cu) : VirtualSitesKernel(name, platform), cu(cu) {
}
/**
* Initialize the kernel.
*
* @param system the System this kernel will be applied to
*/
void initialize(const System& system);
/**
* Compute the virtual site locations.
*
* @param context the context in which to execute this kernel
*/
void computePositions(ContextImpl& context);
private:
CudaContext& cu;
};
/**
* This kernel is invoked by HarmonicBondForce to calculate the forces acting on the system and the energy of the system.
*/
class CudaCalcHarmonicBondForceKernel : public CalcHarmonicBondForceKernel {
public:
CudaCalcHarmonicBondForceKernel(std::string name, const Platform& platform, CudaContext& cu, System& system) : CalcHarmonicBondForceKernel(name, platform),
hasInitializedKernel(false), cu(cu), system(system), params(NULL) {
}
~CudaCalcHarmonicBondForceKernel();
/**
* Initialize the kernel.
*
* @param system the System this kernel will be applied to
* @param force the HarmonicBondForce this kernel will be used for
*/
void initialize(const System& system, const HarmonicBondForce& force);
/**
* Execute the kernel to calculate the forces and/or energy.
*
* @param context the context in which to execute this kernel
* @param includeForces true if forces should be calculated
* @param includeEnergy true if the energy should be calculated
* @return the potential energy due to the force
*/
double execute(ContextImpl& context, bool includeForces, bool includeEnergy);
/**
* Copy changed parameters over to a context.
*
* @param context the context to copy parameters to
* @param force the HarmonicBondForce to copy the parameters from
*/
void copyParametersToContext(ContextImpl& context, const HarmonicBondForce& force);
private:
int numBonds;
bool hasInitializedKernel;
CudaContext& cu;
System& system;
CudaArray* params;
};
/**
* This kernel is invoked by CustomBondForce to calculate the forces acting on the system and the energy of the system.
*/
class CudaCalcCustomBondForceKernel : public CalcCustomBondForceKernel {
public:
CudaCalcCustomBondForceKernel(std::string name, const Platform& platform, CudaContext& cu, System& system) : CalcCustomBondForceKernel(name, platform),
hasInitializedKernel(false), cu(cu), system(system), params(NULL), globals(NULL) {
}
~CudaCalcCustomBondForceKernel();
/**
* Initialize the kernel.
*
* @param system the System this kernel will be applied to
* @param force the CustomBondForce this kernel will be used for
*/
void initialize(const System& system, const CustomBondForce& force);
/**
* Execute the kernel to calculate the forces and/or energy.
*
* @param context the context in which to execute this kernel
* @param includeForces true if forces should be calculated
* @param includeEnergy true if the energy should be calculated
* @return the potential energy due to the force
*/
double execute(ContextImpl& context, bool includeForces, bool includeEnergy);
/**
* Copy changed parameters over to a context.
*
* @param context the context to copy parameters to
* @param force the CustomBondForce to copy the parameters from
*/
void copyParametersToContext(ContextImpl& context, const CustomBondForce& force);
private:
int numBonds;
bool hasInitializedKernel;
CudaContext& cu;
System& system;
CudaParameterSet* params;
CudaArray* globals;
std::vector globalParamNames;
std::vector globalParamValues;
};
/**
* This kernel is invoked by HarmonicAngleForce to calculate the forces acting on the system and the energy of the system.
*/
class CudaCalcHarmonicAngleForceKernel : public CalcHarmonicAngleForceKernel {
public:
CudaCalcHarmonicAngleForceKernel(std::string name, const Platform& platform, CudaContext& cu, System& system) : CalcHarmonicAngleForceKernel(name, platform),
hasInitializedKernel(false), cu(cu), system(system), params(NULL) {
}
~CudaCalcHarmonicAngleForceKernel();
/**
* Initialize the kernel.
*
* @param system the System this kernel will be applied to
* @param force the HarmonicAngleForce this kernel will be used for
*/
void initialize(const System& system, const HarmonicAngleForce& force);
/**
* Execute the kernel to calculate the forces and/or energy.
*
* @param context the context in which to execute this kernel
* @param includeForces true if forces should be calculated
* @param includeEnergy true if the energy should be calculated
* @return the potential energy due to the force
*/
double execute(ContextImpl& context, bool includeForces, bool includeEnergy);
/**
* Copy changed parameters over to a context.
*
* @param context the context to copy parameters to
* @param force the HarmonicAngleForce to copy the parameters from
*/
void copyParametersToContext(ContextImpl& context, const HarmonicAngleForce& force);
private:
int numAngles;
bool hasInitializedKernel;
CudaContext& cu;
System& system;
CudaArray* params;
};
/**
* This kernel is invoked by CustomAngleForce to calculate the forces acting on the system and the energy of the system.
*/
class CudaCalcCustomAngleForceKernel : public CalcCustomAngleForceKernel {
public:
CudaCalcCustomAngleForceKernel(std::string name, const Platform& platform, CudaContext& cu, System& system) : CalcCustomAngleForceKernel(name, platform),
hasInitializedKernel(false), cu(cu), system(system), params(NULL), globals(NULL) {
}
~CudaCalcCustomAngleForceKernel();
/**
* Initialize the kernel.
*
* @param system the System this kernel will be applied to
* @param force the CustomAngleForce this kernel will be used for
*/
void initialize(const System& system, const CustomAngleForce& force);
/**
* Execute the kernel to calculate the forces and/or energy.
*
* @param context the context in which to execute this kernel
* @param includeForces true if forces should be calculated
* @param includeEnergy true if the energy should be calculated
* @return the potential energy due to the force
*/
double execute(ContextImpl& context, bool includeForces, bool includeEnergy);
/**
* Copy changed parameters over to a context.
*
* @param context the context to copy parameters to
* @param force the CustomAngleForce to copy the parameters from
*/
void copyParametersToContext(ContextImpl& context, const CustomAngleForce& force);
private:
int numAngles;
bool hasInitializedKernel;
CudaContext& cu;
System& system;
CudaParameterSet* params;
CudaArray* globals;
std::vector globalParamNames;
std::vector globalParamValues;
};
/**
* This kernel is invoked by PeriodicTorsionForce to calculate the forces acting on the system and the energy of the system.
*/
class CudaCalcPeriodicTorsionForceKernel : public CalcPeriodicTorsionForceKernel {
public:
CudaCalcPeriodicTorsionForceKernel(std::string name, const Platform& platform, CudaContext& cu, System& system) : CalcPeriodicTorsionForceKernel(name, platform),
hasInitializedKernel(false), cu(cu), system(system), params(NULL) {
}
~CudaCalcPeriodicTorsionForceKernel();
/**
* Initialize the kernel.
*
* @param system the System this kernel will be applied to
* @param force the PeriodicTorsionForce this kernel will be used for
*/
void initialize(const System& system, const PeriodicTorsionForce& force);
/**
* Execute the kernel to calculate the forces and/or energy.
*
* @param context the context in which to execute this kernel
* @param includeForces true if forces should be calculated
* @param includeEnergy true if the energy should be calculated
* @return the potential energy due to the force
*/
double execute(ContextImpl& context, bool includeForces, bool includeEnergy);
/**
* Copy changed parameters over to a context.
*
* @param context the context to copy parameters to
* @param force the PeriodicTorsionForce to copy the parameters from
*/
void copyParametersToContext(ContextImpl& context, const PeriodicTorsionForce& force);
private:
int numTorsions;
bool hasInitializedKernel;
CudaContext& cu;
System& system;
CudaArray* params;
};
/**
* This kernel is invoked by RBTorsionForce to calculate the forces acting on the system and the energy of the system.
*/
class CudaCalcRBTorsionForceKernel : public CalcRBTorsionForceKernel {
public:
CudaCalcRBTorsionForceKernel(std::string name, const Platform& platform, CudaContext& cu, System& system) : CalcRBTorsionForceKernel(name, platform),
hasInitializedKernel(false), cu(cu), system(system), params1(NULL), params2(NULL) {
}
~CudaCalcRBTorsionForceKernel();
/**
* Initialize the kernel.
*
* @param system the System this kernel will be applied to
* @param force the RBTorsionForce this kernel will be used for
*/
void initialize(const System& system, const RBTorsionForce& force);
/**
* Execute the kernel to calculate the forces and/or energy.
*
* @param context the context in which to execute this kernel
* @param includeForces true if forces should be calculated
* @param includeEnergy true if the energy should be calculated
* @return the potential energy due to the force
*/
double execute(ContextImpl& context, bool includeForces, bool includeEnergy);
/**
* Copy changed parameters over to a context.
*
* @param context the context to copy parameters to
* @param force the RBTorsionForce to copy the parameters from
*/
void copyParametersToContext(ContextImpl& context, const RBTorsionForce& force);
private:
int numTorsions;
bool hasInitializedKernel;
CudaContext& cu;
System& system;
CudaArray* params1;
CudaArray* params2;
};
/**
* This kernel is invoked by CMAPTorsionForce to calculate the forces acting on the system and the energy of the system.
*/
class CudaCalcCMAPTorsionForceKernel : public CalcCMAPTorsionForceKernel {
public:
CudaCalcCMAPTorsionForceKernel(std::string name, const Platform& platform, CudaContext& cu, System& system) : CalcCMAPTorsionForceKernel(name, platform),
hasInitializedKernel(false), cu(cu), system(system), coefficients(NULL), mapPositions(NULL), torsionMaps(NULL) {
}
~CudaCalcCMAPTorsionForceKernel();
/**
* Initialize the kernel.
*
* @param system the System this kernel will be applied to
* @param force the CMAPTorsionForce this kernel will be used for
*/
void initialize(const System& system, const CMAPTorsionForce& force);
/**
* Execute the kernel to calculate the forces and/or energy.
*
* @param context the context in which to execute this kernel
* @param includeForces true if forces should be calculated
* @param includeEnergy true if the energy should be calculated
* @return the potential energy due to the force
*/
double execute(ContextImpl& context, bool includeForces, bool includeEnergy);
private:
int numTorsions;
bool hasInitializedKernel;
CudaContext& cu;
System& system;
CudaArray* coefficients;
CudaArray* mapPositions;
CudaArray* torsionMaps;
};
/**
* This kernel is invoked by CustomTorsionForce to calculate the forces acting on the system and the energy of the system.
*/
class CudaCalcCustomTorsionForceKernel : public CalcCustomTorsionForceKernel {
public:
CudaCalcCustomTorsionForceKernel(std::string name, const Platform& platform, CudaContext& cu, System& system) : CalcCustomTorsionForceKernel(name, platform),
hasInitializedKernel(false), cu(cu), system(system), params(NULL), globals(NULL) {
}
~CudaCalcCustomTorsionForceKernel();
/**
* Initialize the kernel.
*
* @param system the System this kernel will be applied to
* @param force the CustomTorsionForce this kernel will be used for
*/
void initialize(const System& system, const CustomTorsionForce& force);
/**
* Execute the kernel to calculate the forces and/or energy.
*
* @param context the context in which to execute this kernel
* @param includeForces true if forces should be calculated
* @param includeEnergy true if the energy should be calculated
* @return the potential energy due to the force
*/
double execute(ContextImpl& context, bool includeForces, bool includeEnergy);
/**
* Copy changed parameters over to a context.
*
* @param context the context to copy parameters to
* @param force the CustomTorsionForce to copy the parameters from
*/
void copyParametersToContext(ContextImpl& context, const CustomTorsionForce& force);
private:
int numTorsions;
bool hasInitializedKernel;
CudaContext& cu;
System& system;
CudaParameterSet* params;
CudaArray* globals;
std::vector globalParamNames;
std::vector globalParamValues;
};
/**
* This kernel is invoked by NonbondedForce to calculate the forces acting on the system.
*/
class CudaCalcNonbondedForceKernel : public CalcNonbondedForceKernel {
public:
CudaCalcNonbondedForceKernel(std::string name, const Platform& platform, CudaContext& cu, System& system) : CalcNonbondedForceKernel(name, platform),
cu(cu), hasInitializedFFT(false), sigmaEpsilon(NULL), exceptionParams(NULL), cosSinSums(NULL), pmeGrid(NULL),
pmeBsplineModuliX(NULL), pmeBsplineModuliY(NULL), pmeBsplineModuliZ(NULL), pmeBsplineTheta(NULL), pmeBsplineDTheta(NULL),
pmeAtomRange(NULL), pmeAtomGridIndex(NULL), sort(NULL) {
}
~CudaCalcNonbondedForceKernel();
/**
* Initialize the kernel.
*
* @param system the System this kernel will be applied to
* @param force the NonbondedForce this kernel will be used for
*/
void initialize(const System& system, const NonbondedForce& force);
/**
* Execute the kernel to calculate the forces and/or energy.
*
* @param context the context in which to execute this kernel
* @param includeForces true if forces should be calculated
* @param includeEnergy true if the energy should be calculated
* @param includeDirect true if direct space interactions should be included
* @param includeReciprocal true if reciprocal space interactions should be included
* @return the potential energy due to the force
*/
double execute(ContextImpl& context, bool includeForces, bool includeEnergy, bool includeDirect, bool includeReciprocal);
/**
* Copy changed parameters over to a context.
*
* @param context the context to copy parameters to
* @param force the NonbondedForce to copy the parameters from
*/
void copyParametersToContext(ContextImpl& context, const NonbondedForce& force);
private:
class SortTrait : public CudaSort::SortTrait {
int getDataSize() const {return 8;}
int getKeySize() const {return 4;}
const char* getDataType() const {return "int2";}
const char* getKeyType() const {return "int";}
const char* getMinKey() const {return "INT_MIN";}
const char* getMaxKey() const {return "INT_MAX";}
const char* getMaxValue() const {return "make_int2(INT_MAX, INT_MAX)";}
const char* getSortKey() const {return "value.y";}
};
CudaContext& cu;
bool hasInitializedFFT;
CudaArray* sigmaEpsilon;
CudaArray* exceptionParams;
CudaArray* cosSinSums;
CudaArray* pmeGrid;
CudaArray* pmeBsplineModuliX;
CudaArray* pmeBsplineModuliY;
CudaArray* pmeBsplineModuliZ;
CudaArray* pmeBsplineTheta;
CudaArray* pmeBsplineDTheta;
CudaArray* pmeAtomRange;
CudaArray* pmeAtomGridIndex;
CudaSort* sort;
cufftHandle fft;
CUfunction ewaldSumsKernel;
CUfunction ewaldForcesKernel;
CUfunction pmeGridIndexKernel;
CUfunction pmeAtomRangeKernel;
CUfunction pmeZIndexKernel;
CUfunction pmeUpdateBsplinesKernel;
CUfunction pmeSpreadChargeKernel;
CUfunction pmeFinishSpreadChargeKernel;
CUfunction pmeConvolutionKernel;
CUfunction pmeInterpolateForceKernel;
std::map pmeDefines;
std::vector > exceptionAtoms;
double ewaldSelfEnergy, dispersionCoefficient, alpha;
int interpolateForceThreads;
bool hasCoulomb, hasLJ;
static const int PmeOrder = 5;
};
///**
// * This kernel is invoked by CustomNonbondedForce to calculate the forces acting on the system.
// */
//class CudaCalcCustomNonbondedForceKernel : public CalcCustomNonbondedForceKernel {
//public:
// CudaCalcCustomNonbondedForceKernel(std::string name, const Platform& platform, CudaContext& cu, System& system) : CalcCustomNonbondedForceKernel(name, platform),
// hasInitializedKernel(false), cu(cu), params(NULL), globals(NULL), tabulatedFunctionParams(NULL), system(system) {
// }
// ~CudaCalcCustomNonbondedForceKernel();
// /**
// * Initialize the kernel.
// *
// * @param system the System this kernel will be applied to
// * @param force the CustomNonbondedForce this kernel will be used for
// */
// void initialize(const System& system, const CustomNonbondedForce& force);
// /**
// * Execute the kernel to calculate the forces and/or energy.
// *
// * @param context the context in which to execute this kernel
// * @param includeForces true if forces should be calculated
// * @param includeEnergy true if the energy should be calculated
// * @return the potential energy due to the force
// */
// double execute(ContextImpl& context, bool includeForces, bool includeEnergy);
// /**
// * Copy changed parameters over to a context.
// *
// * @param context the context to copy parameters to
// * @param force the CustomNonbondedForce to copy the parameters from
// */
// void copyParametersToContext(ContextImpl& context, const CustomNonbondedForce& force);
//private:
// bool hasInitializedKernel;
// CudaContext& cu;
// CudaParameterSet* params;
// CudaArray* globals;
// CudaArray* tabulatedFunctionParams;
// std::vector globalParamNames;
// std::vector globalParamValues;
// std::vector*> tabulatedFunctions;
// System& system;
//};
//
///**
// * This kernel is invoked by GBSAOBCForce to calculate the forces acting on the system.
// */
//class CudaCalcGBSAOBCForceKernel : public CalcGBSAOBCForceKernel {
//public:
// CudaCalcGBSAOBCForceKernel(std::string name, const Platform& platform, CudaContext& cu) : CalcGBSAOBCForceKernel(name, platform), cu(cu),
// hasCreatedKernels(false), params(NULL), bornSum(NULL), longBornSum(NULL), bornRadii(NULL), bornForce(NULL),
// longBornForce(NULL), obcChain(NULL) {
// }
// ~CudaCalcGBSAOBCForceKernel();
// /**
// * Initialize the kernel.
// *
// * @param system the System this kernel will be applied to
// * @param force the GBSAOBCForce this kernel will be used for
// */
// void initialize(const System& system, const GBSAOBCForce& force);
// /**
// * Execute the kernel to calculate the forces and/or energy.
// *
// * @param context the context in which to execute this kernel
// * @param includeForces true if forces should be calculated
// * @param includeEnergy true if the energy should be calculated
// * @return the potential energy due to the force
// */
// double execute(ContextImpl& context, bool includeForces, bool includeEnergy);
// /**
// * Copy changed parameters over to a context.
// *
// * @param context the context to copy parameters to
// * @param force the GBSAOBCForce to copy the parameters from
// */
// void copyParametersToContext(ContextImpl& context, const GBSAOBCForce& force);
//private:
// double prefactor;
// bool hasCreatedKernels;
// int maxTiles;
// CudaContext& cu;
// CudaArray* params;
// CudaArray* bornSum;
// CudaArray* longBornSum;
// CudaArray* bornRadii;
// CudaArray* bornForce;
// CudaArray* longBornForce;
// CudaArray* obcChain;
// CUfunction computeBornSumKernel;
// CUfunction reduceBornSumKernel;
// CUfunction force1Kernel;
// CUfunction reduceBornForceKernel;
//};
//
///**
// * This kernel is invoked by CustomGBForce to calculate the forces acting on the system.
// */
//class CudaCalcCustomGBForceKernel : public CalcCustomGBForceKernel {
//public:
// CudaCalcCustomGBForceKernel(std::string name, const Platform& platform, CudaContext& cu, System& system) : CalcCustomGBForceKernel(name, platform),
// hasInitializedKernels(false), cu(cu), params(NULL), computedValues(NULL), energyDerivs(NULL), longEnergyDerivs(NULL), globals(NULL),
// valueBuffers(NULL), longValueBuffers(NULL), tabulatedFunctionParams(NULL), system(system) {
// }
// ~CudaCalcCustomGBForceKernel();
// /**
// * Initialize the kernel.
// *
// * @param system the System this kernel will be applied to
// * @param force the CustomGBForce this kernel will be used for
// */
// void initialize(const System& system, const CustomGBForce& force);
// /**
// * Execute the kernel to calculate the forces and/or energy.
// *
// * @param context the context in which to execute this kernel
// * @param includeForces true if forces should be calculated
// * @param includeEnergy true if the energy should be calculated
// * @return the potential energy due to the force
// */
// double execute(ContextImpl& context, bool includeForces, bool includeEnergy);
// /**
// * Copy changed parameters over to a context.
// *
// * @param context the context to copy parameters to
// * @param force the CustomGBForce to copy the parameters from
// */
// void copyParametersToContext(ContextImpl& context, const CustomGBForce& force);
//private:
// bool hasInitializedKernels, needParameterGradient;
// int maxTiles, numComputedValues;
// CudaContext& cu;
// CudaParameterSet* params;
// CudaParameterSet* computedValues;
// CudaParameterSet* energyDerivs;
// CudaArray* longEnergyDerivs;
// CudaArray* globals;
// CudaArray* valueBuffers;
// CudaArray* longValueBuffers;
// CudaArray* tabulatedFunctionParams;
// std::vector globalParamNames;
// std::vector globalParamValues;
// std::vector*> tabulatedFunctions;
// std::vector pairValueUsesParam, pairEnergyUsesParam, pairEnergyUsesValue;
// System& system;
// CUfunction pairValueKernel, perParticleValueKernel, pairEnergyKernel, perParticleEnergyKernel, gradientChainRuleKernel;
//};
/**
* This kernel is invoked by CustomExternalForce to calculate the forces acting on the system and the energy of the system.
*/
class CudaCalcCustomExternalForceKernel : public CalcCustomExternalForceKernel {
public:
CudaCalcCustomExternalForceKernel(std::string name, const Platform& platform, CudaContext& cu, System& system) : CalcCustomExternalForceKernel(name, platform),
hasInitializedKernel(false), cu(cu), system(system), params(NULL), globals(NULL) {
}
~CudaCalcCustomExternalForceKernel();
/**
* Initialize the kernel.
*
* @param system the System this kernel will be applied to
* @param force the CustomExternalForce this kernel will be used for
*/
void initialize(const System& system, const CustomExternalForce& force);
/**
* Execute the kernel to calculate the forces and/or energy.
*
* @param context the context in which to execute this kernel
* @param includeForces true if forces should be calculated
* @param includeEnergy true if the energy should be calculated
* @return the potential energy due to the force
*/
double execute(ContextImpl& context, bool includeForces, bool includeEnergy);
/**
* Copy changed parameters over to a context.
*
* @param context the context to copy parameters to
* @param force the CustomExternalForce to copy the parameters from
*/
void copyParametersToContext(ContextImpl& context, const CustomExternalForce& force);
private:
int numParticles;
bool hasInitializedKernel;
CudaContext& cu;
System& system;
CudaParameterSet* params;
CudaArray* globals;
std::vector globalParamNames;
std::vector globalParamValues;
};
///**
// * This kernel is invoked by CustomHbondForce to calculate the forces acting on the system.
// */
//class CudaCalcCustomHbondForceKernel : public CalcCustomHbondForceKernel {
//public:
// CudaCalcCustomHbondForceKernel(std::string name, const Platform& platform, CudaContext& cu, System& system) : CalcCustomHbondForceKernel(name, platform),
// hasInitializedKernel(false), cu(cu), donorParams(NULL), acceptorParams(NULL), donors(NULL), acceptors(NULL),
// donorBufferIndices(NULL), acceptorBufferIndices(NULL), globals(NULL), donorExclusions(NULL), acceptorExclusions(NULL),
// tabulatedFunctionParams(NULL), system(system) {
// }
// ~CudaCalcCustomHbondForceKernel();
// /**
// * Initialize the kernel.
// *
// * @param system the System this kernel will be applied to
// * @param force the CustomHbondForce this kernel will be used for
// */
// void initialize(const System& system, const CustomHbondForce& force);
// /**
// * Execute the kernel to calculate the forces and/or energy.
// *
// * @param context the context in which to execute this kernel
// * @param includeForces true if forces should be calculated
// * @param includeEnergy true if the energy should be calculated
// * @return the potential energy due to the force
// */
// double execute(ContextImpl& context, bool includeForces, bool includeEnergy);
// /**
// * Copy changed parameters over to a context.
// *
// * @param context the context to copy parameters to
// * @param force the CustomHbondForce to copy the parameters from
// */
// void copyParametersToContext(ContextImpl& context, const CustomHbondForce& force);
//private:
// int numDonors, numAcceptors;
// bool hasInitializedKernel;
// CudaContext& cu;
// CudaParameterSet* donorParams;
// CudaParameterSet* acceptorParams;
// CudaArray* globals;
// CudaArray* donors;
// CudaArray* acceptors;
// CudaArray* donorBufferIndices;
// CudaArray* acceptorBufferIndices;
// CudaArray* donorExclusions;
// CudaArray* acceptorExclusions;
// CudaArray* tabulatedFunctionParams;
// std::vector globalParamNames;
// std::vector globalParamValues;
// std::vector*> tabulatedFunctions;
// System& system;
// CUfunction donorKernel, acceptorKernel;
//};
/**
* This kernel is invoked by CustomCompoundBondForce to calculate the forces acting on the system.
*/
class CudaCalcCustomCompoundBondForceKernel : public CalcCustomCompoundBondForceKernel {
public:
CudaCalcCustomCompoundBondForceKernel(std::string name, const Platform& platform, CudaContext& cu, System& system) : CalcCustomCompoundBondForceKernel(name, platform),
cu(cu), params(NULL), globals(NULL), tabulatedFunctionParams(NULL), system(system) {
}
~CudaCalcCustomCompoundBondForceKernel();
/**
* Initialize the kernel.
*
* @param system the System this kernel will be applied to
* @param force the CustomCompoundBondForce this kernel will be used for
*/
void initialize(const System& system, const CustomCompoundBondForce& force);
/**
* Execute the kernel to calculate the forces and/or energy.
*
* @param context the context in which to execute this kernel
* @param includeForces true if forces should be calculated
* @param includeEnergy true if the energy should be calculated
* @return the potential energy due to the force
*/
double execute(ContextImpl& context, bool includeForces, bool includeEnergy);
/**
* Copy changed parameters over to a context.
*
* @param context the context to copy parameters to
* @param force the CustomCompoundBondForce to copy the parameters from
*/
void copyParametersToContext(ContextImpl& context, const CustomCompoundBondForce& force);
private:
int numBonds;
CudaContext& cu;
CudaParameterSet* params;
CudaArray* globals;
CudaArray* tabulatedFunctionParams;
std::vector globalParamNames;
std::vector globalParamValues;
std::vector tabulatedFunctions;
System& system;
};
/**
* This kernel is invoked by VerletIntegrator to take one time step.
*/
class CudaIntegrateVerletStepKernel : public IntegrateVerletStepKernel {
public:
CudaIntegrateVerletStepKernel(std::string name, const Platform& platform, CudaContext& cu) : IntegrateVerletStepKernel(name, platform), cu(cu) {
}
~CudaIntegrateVerletStepKernel();
/**
* Initialize the kernel.
*
* @param system the System this kernel will be applied to
* @param integrator the VerletIntegrator this kernel will be used for
*/
void initialize(const System& system, const VerletIntegrator& integrator);
/**
* Execute the kernel.
*
* @param context the context in which to execute this kernel
* @param integrator the VerletIntegrator this kernel is being used for
*/
void execute(ContextImpl& context, const VerletIntegrator& integrator);
private:
CudaContext& cu;
double prevStepSize;
CUfunction kernel1, kernel2;
};
/**
* This kernel is invoked by LangevinIntegrator to take one time step.
*/
class CudaIntegrateLangevinStepKernel : public IntegrateLangevinStepKernel {
public:
CudaIntegrateLangevinStepKernel(std::string name, const Platform& platform, CudaContext& cu) : IntegrateLangevinStepKernel(name, platform), cu(cu), params(NULL) {
}
~CudaIntegrateLangevinStepKernel();
/**
* Initialize the kernel, setting up the particle masses.
*
* @param system the System this kernel will be applied to
* @param integrator the LangevinIntegrator this kernel will be used for
*/
void initialize(const System& system, const LangevinIntegrator& integrator);
/**
* Execute the kernel.
*
* @param context the context in which to execute this kernel
* @param integrator the LangevinIntegrator this kernel is being used for
*/
void execute(ContextImpl& context, const LangevinIntegrator& integrator);
private:
CudaContext& cu;
double prevTemp, prevFriction, prevStepSize;
CudaArray* params;
CUfunction kernel1, kernel2;
};
/**
* This kernel is invoked by BrownianIntegrator to take one time step.
*/
class CudaIntegrateBrownianStepKernel : public IntegrateBrownianStepKernel {
public:
CudaIntegrateBrownianStepKernel(std::string name, const Platform& platform, CudaContext& cu) : IntegrateBrownianStepKernel(name, platform), cu(cu) {
}
~CudaIntegrateBrownianStepKernel();
/**
* Initialize the kernel.
*
* @param system the System this kernel will be applied to
* @param integrator the BrownianIntegrator this kernel will be used for
*/
void initialize(const System& system, const BrownianIntegrator& integrator);
/**
* Execute the kernel.
*
* @param context the context in which to execute this kernel
* @param integrator the BrownianIntegrator this kernel is being used for
*/
void execute(ContextImpl& context, const BrownianIntegrator& integrator);
private:
CudaContext& cu;
double prevTemp, prevFriction, prevStepSize;
CUfunction kernel1, kernel2;
};
/**
* This kernel is invoked by VariableVerletIntegrator to take one time step.
*/
class CudaIntegrateVariableVerletStepKernel : public IntegrateVariableVerletStepKernel {
public:
CudaIntegrateVariableVerletStepKernel(std::string name, const Platform& platform, CudaContext& cu) : IntegrateVariableVerletStepKernel(name, platform), cu(cu) {
}
~CudaIntegrateVariableVerletStepKernel();
/**
* Initialize the kernel.
*
* @param system the System this kernel will be applied to
* @param integrator the VerletIntegrator this kernel will be used for
*/
void initialize(const System& system, const VariableVerletIntegrator& integrator);
/**
* Execute the kernel.
*
* @param context the context in which to execute this kernel
* @param integrator the VerletIntegrator this kernel is being used for
* @param maxTime the maximum time beyond which the simulation should not be advanced
* @return the size of the step that was taken
*/
double execute(ContextImpl& context, const VariableVerletIntegrator& integrator, double maxTime);
private:
CudaContext& cu;
int blockSize;
CUfunction kernel1, kernel2, selectSizeKernel;
};
/**
* This kernel is invoked by VariableLangevinIntegrator to take one time step.
*/
class CudaIntegrateVariableLangevinStepKernel : public IntegrateVariableLangevinStepKernel {
public:
CudaIntegrateVariableLangevinStepKernel(std::string name, const Platform& platform, CudaContext& cu) : IntegrateVariableLangevinStepKernel(name, platform),
cu(cu), params(NULL) {
}
~CudaIntegrateVariableLangevinStepKernel();
/**
* Initialize the kernel, setting up the particle masses.
*
* @param system the System this kernel will be applied to
* @param integrator the VariableLangevinIntegrator this kernel will be used for
*/
void initialize(const System& system, const VariableLangevinIntegrator& integrator);
/**
* Execute the kernel.
*
* @param context the context in which to execute this kernel
* @param integrator the VariableLangevinIntegrator this kernel is being used for
* @param maxTime the maximum time beyond which the simulation should not be advanced
* @return the size of the step that was taken
*/
double execute(ContextImpl& context, const VariableLangevinIntegrator& integrator, double maxTime);
private:
CudaContext& cu;
int blockSize;
CudaArray* params;
CUfunction kernel1, kernel2, selectSizeKernel;
double prevTemp, prevFriction, prevErrorTol;
};
///**
// * This kernel is invoked by CustomIntegrator to take one time step.
// */
//class CudaIntegrateCustomStepKernel : public IntegrateCustomStepKernel {
//public:
// CudaIntegrateCustomStepKernel(std::string name, const Platform& platform, CudaContext& cu) : IntegrateCustomStepKernel(name, platform), cu(cu),
// hasInitializedKernels(false), localValuesAreCurrent(false), globalValues(NULL), contextParameterValues(NULL), sumBuffer(NULL), energy(NULL),
// uniformRandoms(NULL), randomSeed(NULL), perDofValues(NULL) {
// }
// ~CudaIntegrateCustomStepKernel();
// /**
// * Initialize the kernel.
// *
// * @param system the System this kernel will be applied to
// * @param integrator the CustomIntegrator this kernel will be used for
// */
// void initialize(const System& system, const CustomIntegrator& integrator);
// /**
// * Execute the kernel.
// *
// * @param context the context in which to execute this kernel
// * @param integrator the CustomIntegrator this kernel is being used for
// * @param forcesAreValid if the context has been modified since the last time step, this will be
// * false to show that cached forces are invalid and must be recalculated.
// * On exit, this should specify whether the cached forces are valid at the
// * end of the step.
// */
// void execute(ContextImpl& context, CustomIntegrator& integrator, bool& forcesAreValid);
// /**
// * Get the values of all global variables.
// *
// * @param context the context in which to execute this kernel
// * @param values on exit, this contains the values
// */
// void getGlobalVariables(ContextImpl& context, std::vector& values) const;
// /**
// * Set the values of all global variables.
// *
// * @param context the context in which to execute this kernel
// * @param values a vector containing the values
// */
// void setGlobalVariables(ContextImpl& context, const std::vector& values);
// /**
// * Get the values of a per-DOF variable.
// *
// * @param context the context in which to execute this kernel
// * @param variable the index of the variable to get
// * @param values on exit, this contains the values
// */
// void getPerDofVariable(ContextImpl& context, int variable, std::vector& values) const;
// /**
// * Set the values of a per-DOF variable.
// *
// * @param context the context in which to execute this kernel
// * @param variable the index of the variable to get
// * @param values a vector containing the values
// */
// void setPerDofVariable(ContextImpl& context, int variable, const std::vector& values);
//private:
// class ReorderListener;
// std::string createGlobalComputation(const std::string& variable, const Lepton::ParsedExpression& expr, CustomIntegrator& integrator, const std::string& energyName);
// std::string createPerDofComputation(const std::string& variable, const Lepton::ParsedExpression& expr, int component, CustomIntegrator& integrator, const std::string& forceName, const std::string& energyName);
// void recordChangedParameters(ContextImpl& context);
// CudaContext& cu;
// double prevStepSize;
// int numGlobalVariables;
// bool hasInitializedKernels, deviceValuesAreCurrent, modifiesParameters;
// mutable bool localValuesAreCurrent;
// CudaArray* globalValues;
// CudaArray* contextParameterValues;
// CudaArray* sumBuffer;
// CudaArray* energy;
// CudaArray* uniformRandoms;
// CudaArray* randomSeed;
// CudaParameterSet* perDofValues;
// mutable std::vector > localPerDofValues;
// std::vector > kernels;
// CUfunction sumEnergyKernel, randomKernel;
// std::vector stepType;
// std::vector needsForces;
// std::vector needsEnergy;
// std::vector invalidatesForces;
// std::vector merged;
// std::vector forceGroup;
// std::vector requiredGaussian;
// std::vector requiredUniform;
// std::vector parameterNames;
//};
/**
* This kernel is invoked by AndersenThermostat at the start of each time step to adjust the particle velocities.
*/
class CudaApplyAndersenThermostatKernel : public ApplyAndersenThermostatKernel {
public:
CudaApplyAndersenThermostatKernel(std::string name, const Platform& platform, CudaContext& cu) : ApplyAndersenThermostatKernel(name, platform), cu(cu),
atomGroups(NULL) {
}
~CudaApplyAndersenThermostatKernel();
/**
* Initialize the kernel.
*
* @param system the System this kernel will be applied to
* @param thermostat the AndersenThermostat this kernel will be used for
*/
void initialize(const System& system, const AndersenThermostat& thermostat);
/**
* Execute the kernel.
*
* @param context the context in which to execute this kernel
*/
void execute(ContextImpl& context);
private:
CudaContext& cu;
int randomSeed;
CudaArray* atomGroups;
CUfunction kernel;
};
/**
* This kernel is invoked by MonteCarloBarostat to adjust the periodic box volume
*/
class CudaApplyMonteCarloBarostatKernel : public ApplyMonteCarloBarostatKernel {
public:
CudaApplyMonteCarloBarostatKernel(std::string name, const Platform& platform, CudaContext& cu) : ApplyMonteCarloBarostatKernel(name, platform), cu(cu),
hasInitializedKernels(false), savedPositions(NULL), moleculeAtoms(NULL), moleculeStartIndex(NULL) {
}
~CudaApplyMonteCarloBarostatKernel();
/**
* Initialize the kernel.
*
* @param system the System this kernel will be applied to
* @param barostat the MonteCarloBarostat this kernel will be used for
*/
void initialize(const System& system, const MonteCarloBarostat& barostat);
/**
* Attempt a Monte Carlo step, scaling particle positions (or cluster centers) by a specified value.
* This is called BEFORE the periodic box size is modified. It should begin by translating each particle
* or cluster into the first periodic box, so that coordinates will still be correct after the box size
* is changed.
*
* @param context the context in which to execute this kernel
* @param scale the scale factor by which to multiply particle positions
*/
void scaleCoordinates(ContextImpl& context, double scale);
/**
* Reject the most recent Monte Carlo step, restoring the particle positions to where they were before
* scaleCoordinates() was last called.
*
* @param context the context in which to execute this kernel
*/
void restoreCoordinates(ContextImpl& context);
private:
CudaContext& cu;
bool hasInitializedKernels;
int numMolecules;
CudaArray* savedPositions;
CudaArray* moleculeAtoms;
CudaArray* moleculeStartIndex;
CUfunction kernel;
};
/**
* This kernel is invoked to calculate the kinetic energy of the system.
*/
class CudaCalcKineticEnergyKernel : public CalcKineticEnergyKernel {
public:
CudaCalcKineticEnergyKernel(std::string name, const Platform& platform, CudaContext& cu) : CalcKineticEnergyKernel(name, platform), cu(cu) {
}
/**
* Initialize the kernel.
*
* @param system the System this kernel will be applied to
*/
void initialize(const System& system);
/**
* Execute the kernel.
*
* @param context the context in which to execute this kernel
*/
double execute(ContextImpl& context);
private:
CudaContext& cu;
std::vector masses;
};
/**
* This kernel is invoked to remove center of mass motion from the system.
*/
class CudaRemoveCMMotionKernel : public RemoveCMMotionKernel {
public:
CudaRemoveCMMotionKernel(std::string name, const Platform& platform, CudaContext& cu) : RemoveCMMotionKernel(name, platform), cu(cu), cmMomentum(NULL) {
}
~CudaRemoveCMMotionKernel();
/**
* Initialize the kernel, setting up the particle masses.
*
* @param system the System this kernel will be applied to
* @param force the CMMotionRemover this kernel will be used for
*/
void initialize(const System& system, const CMMotionRemover& force);
/**
* Execute the kernel.
*
* @param context the context in which to execute this kernel
*/
void execute(ContextImpl& context);
private:
CudaContext& cu;
int frequency;
CudaArray* cmMomentum;
CUfunction kernel1, kernel2;
};
} // namespace OpenMM
#endif /*OPENMM_CUDAKERNELS_H_*/